Illumination apparatus including semiconductor light emitting diodes

ABSTRACT

An illumination apparatus of a high efficiency light emitting element and a driving circuit of a light emitting element controlling a series and parallel connection relationship between light emitting groups according to a voltage level of a driving voltage and controlling a sequential driving of the light emitting groups at the same time.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 14/344,810, filed on Mar. 13, 2014, which is the National Stage Entry of International Application PCT/KR2012/007409, filed on Sep. 17, 2012, and claims priority from and the benefit of Korean Patent Application No. 10-2011-0093362, filed on Sep. 16, 2011 and Korean Patent Application No. 10-2012-0056307, filed on May 25, 2012, which are incorporated herein by reference for all purposes as if fully set forth herein.

BACKGROUND

1. Field

Example embodiments of the present invention relate in general to the field of an illumination apparatus using semiconductor light emitting diodes (LEDs) as a light source, and more specifically to an illumination apparatus using semiconductor LEDs that can enable all LEDs to emit light in consideration of fluctuations in the magnitude of an alternating current (AC) voltage when a plurality of LEDs are driven using the AC voltage.

2. Discussion of the Background

In recent years, a semiconductor light emitting diode (LED) has been utilized as a light source in many fields due to its various characteristics, such as high efficiency, low power, and high luminance. In particular, the use of illumination systems adopting semiconductor LEDs instead of conventional incandescent light bulbs or fluorescent lamps in the field of illumination has rapidly increased in recent times.

Since conventional illumination apparatuses using incandescent light bulbs or fluorescent lamps as light sources emit light using commercially available alternating current (AC) voltage, semiconductor LEDs for illumination also should be capable of being driven using an AC voltage.

Typically, to drive semiconductor LEDs using an AC voltage, a circuit may be configured to convert an AC voltage having positive and negative values into a rectifying current voltage having a positive value, and to adjust the number of emitting semiconductor LEDs with fluctuations in the magnitude of the rectifying current voltage.

In the above-described typical technique, with fluctuations in the magnitude of the rectifying current voltage, some of the plurality of semiconductor LEDs may continuously emit light over an extended light emitting time, while some of the remaining semiconductor LEDs emit light only when the magnitude of the rectifying current voltage is equal to or higher than a specific value. Thus, semiconductor LEDs constituting an illumination apparatus may have different light emitting times. As a result, some of the semiconductor LEDs constituting the illumination apparatus may wear out earlier than the others, thereby deteriorating a light emitting state of the illumination apparatus and even preventing operation of the illumination apparatus.

SUMMARY OF THE INVENTION

Accordingly, example embodiments of the present invention are provided to substantially obviate one or more problems due to limitations and disadvantages of the related art.

Example embodiments of the present invention provide an illumination apparatus using semiconductor light emitting diodes (LEDs) that can enable all the LEDs to emit light in consideration of fluctuations in the magnitude of an alternating current (AC) voltage for driving the LEDs.

In some example embodiments, an illumination apparatus includes a rectifier configured to receive AC power and generate a driving voltage in the form of a rectifying current voltage, a control signal generator configured to compare the driving voltage with a predetermined reference voltage to generate a sampling signal, and configured to perform a logic operation on the sampling signal to generate a switch control signal and a current control signal, a switch unit configured to perform on/off operations in response to the switch control signal and selectively transmit the driving voltage, a total current controller configured to receive the sampling signal and generate a target voltage as an analog signal, a current controller configured to be enabled in response to the current control signal and having a plurality of driving current controllers configured to receive the target voltage and determine a driving current, and a light emitting unit connected to the current controller and having light emitting diodes (LEDs) configured to perform a light emitting operation.

According to an example embodiment of the present invention, there is provided an illumination apparatus including: a rectifier configured to be connected to alternating current (AC) power to perform a full-wave rectification for an applied AC voltage, and to provide a rectified voltage which is full-wave rectified to a light emitting unit as a driving voltage; the light emitting unit configured to include a first light emitting group to an n-th light emitting group (n is a positive integer of two or more) and to emit light by receiving the driving voltage from the rectifier; a control signal generator configured to generate a switch control signal for controlling a series and parallel connection relationship between the first light emitting group to the n-th light emitting group according to an average voltage level per period of the driving voltage, and generate a current control signal for controlling a sequential driving of at least some of the first light emitting group to the n-th light emitting group according to the voltage level of the driving voltage; a switch unit configured to perform an on or off operation according to the switch control signal to selectively transfer the driving voltage; and a current controller configured to be connected to the first light emitting group to the n-th light emitting group, respectively, and have a first driving current controller to an n-th driving current controller which are selectively activated according to the current control signal.

The control signal generator may be configured to control magnitude of a driving current of the light emitting element according to the average voltage level per period of the driving voltage.

According to another example embodiment of the present invention, there is provided a driving circuit of a light emitting element controlling a driving of a light emitting unit including a first light emitting group to an n-th light emitting group (n is a positive integer of two or more) including: a rectifier configured to be connected to alternating current (AC) power to perform a full-wave rectification for an applied AC voltage, and to provide a rectified voltage which is full-wave rectified to a light emitting unit as a driving voltage; a control signal generator configured to generate a switch control signal for controlling a series and parallel connection relationship between the first light emitting group to the n-th light emitting group according to an average voltage level per period of the driving voltage, and generate a current control signal for controlling a sequential driving of at least some of the first light emitting group to the n-th light emitting group according to the voltage level of the driving voltage; a switch unit configured to perform an on or off operation according to the switch control signal to selectively transfer the driving voltage; and a current controller configured to be connected to the first light emitting group to the n-th light emitting group, respectively, and have a first driving current controller to an n-th driving current controller which are selectively activated according to the current control signal.

The control signal generator may be configured to control magnitude of a driving current of the light emitting element according to the average voltage level per period of the driving voltage.

According to the present invention, an electrical connection relationship among the plurality of LEDs can be appropriately changed with fluctuations in the magnitude of an AC voltage for driving the plurality of LEDs, so that all of the plurality of LEDs employed in the illumination apparatus can emit light.

According to the present invention, all of the plurality of LEDs can emit light, thereby preventing some of the LEDs employed in the illumination apparatus from emitting light for a longer time and deteriorating earlier than the other LEDs.

Furthermore, according to the present invention, when necessary, the total current supplied to all the LEDs can be controlled to be constant or current supplied to each of the LEDs can be controlled to be constant.

While the example embodiments of the present invention and their advantages have been described in detail, it should be understood that various changes, substitutions and alterations may be made herein without departing from the scope of the invention.

BRIEF DESCRIPTION OF DRAWINGS

Example embodiments of the present invention will become more apparent by describing in detail example embodiments of the present invention with reference to the accompanying drawings, in which:

FIG. 1 is a circuit diagram of an illumination apparatus using a semiconductor light emitting diode (LED) according to a first example embodiment of the present invention;

FIG. 2 is a circuit diagram of a control signal generator of FIG. 1;

FIG. 3 is a circuit diagram of respective components of a current controller of FIG. 1;

FIG. 4 is a block diagram of a total current controller of FIG. 1;

FIG. 5 is a graph for explaining operations of the illumination apparatus of FIG. 1, according to the first example embodiment of the present invention;

FIG. 6 is another graph for explaining operations of the illumination apparatus of FIG. 1, according to the first example embodiment of the present invention;

FIG. 7 is a circuit diagram of an illumination apparatus using a semiconductor LED according to a second example embodiment of the present invention;

FIG. 8 is a circuit diagram of a control signal generator according to the second example embodiment of the present invention;

FIG. 9 is a circuit diagram of a switching unit according to the second example embodiment of the present invention.

FIG. 10 is a circuit diagram of an illumination apparatus using a semiconductor light emitting element according to a third example embodiment of the present invention;

FIG. 11A is a waveform diagram showing a relationship between a driving voltage and a driving current of the light emitting element in a case in which the illumination apparatus using the semiconductor light emitting element according to the third example embodiment of the present invention is connected to AC power of 120V(rms); and

FIG. 11B is a waveform diagram showing the relationship between the driving voltage and the driving current of the light emitting element in a case in which the illumination apparatus using the semiconductor light emitting element according to the third example embodiment of the present invention is connected to AC power of 220V(rms).

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS

Example embodiments of the present invention are disclosed herein. However, specific structural and functional details disclosed herein are merely representative for purposes of describing example embodiments of the present invention, however, example embodiments of the present invention may be embodied in many alternate forms and should not be construed as limited to example embodiments of the present invention set forth herein.

Accordingly, while the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that there is no intent to limit the invention to the particular forms disclosed, but on the contrary, the invention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like numbers refer to like elements throughout the description of the figures.

It will be understood that, although the terms first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of the present invention. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items.

It will be understood that when an element is referred to as being “connected” or “coupled” to another element, it can be directly connected or coupled to the other element or intervening elements may be present. In contrast, when an element is referred to as being “directly connected” or “directly coupled” to another element, there are no intervening elements present. Other words used to describe the relationship between elements should be interpreted in a like fashion (i.e., “between” versus “directly between”, “adjacent” versus “directly adjacent”, etc.).

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises”, “comprising,”, “includes” and/or “including”, when used herein, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

It should also be noted that in some alternative implementations, the functions/acts noted in the blocks may occur out of the order noted in the flowcharts. For example, two blocks shown in succession may in fact be executed substantially concurrently or the blocks may sometimes be executed in the reverse order, depending upon the functionality/acts involved.

According to an example embodiment of the present invention, a term “light emitting group” refers to a collection of light emitting elements in which a plurality of light emitting elements (or a plurality of light emitting cells) are connected in series with/in parallel to/in series with and in parallel to each other, so that an operation thereof is controlled (i.e., simultaneously turned on/off) as a single unit according to a control of a control signal generator and a current controller.

In addition, a term ‘first forward voltage level VF1’ refers to a threshold voltage level capable of driving a first light emitting group, a term ‘second forward voltage level VF2’ refers to a threshold voltage level capable of driving the first light emitting group and a second light emitting group which are connected in series with each other (i.e., a voltage level obtained by summing the forward voltage level of the first light emitting group and the forward voltage level of the second light emitting group), and a term ‘third forward voltage level VF3’ refers to a threshold voltage level capable of driving first to third light emitting groups which are connected in series with each other. That is, an ‘n-th forward voltage level VFn’ refers to a threshold voltage level capable of driving first to n-th light emitting groups which are connected in series with each other (i.e., the voltage level obtained by summing all of the forward voltage level of the first light emitting group to the forward voltage level of the n-th light emitting group). Hereinafter, although the present invention will be described based on example embodiments in which all of the light emitting groups have the same forward voltage level, it will be apparent to those skilled in the art that the forward voltage levels of the respective light emitting groups may be designed to be different from each other, if necessary. Therefore, hereinafter, example embodiments of the present invention will be described based on an example embodiment in which the first forward voltage level is 1VF, the second forward voltage level is 2VF, and similarly, the n-th forward voltage level is nVF.

In addition, in the present specification, a ‘first operation section’ refers to a section in which the driving voltage provided to the light emitting unit is the first forward voltage level VF1 or more and is less than the second forward voltage level VF2, a ‘second operation section’ refers to a section in which the driving voltage provided to the light emitting unit is the second forward voltage level VF2 or more and is less than the third forward voltage level VF3, and similarly, an ‘n-th operation section’ refers to a section in which the driving voltage provided to the light emitting unit is the n-th forward voltage level VFn or more.

In addition, in the present specification, a ‘sequential driving’ refers to a driving method in which the first light emitting group to the n-th light emitting group are sequentially tuned on and are sequentially turned off depending on a voltage level of a driving voltage Vin.

In addition, terms such as V1, V2, V3, . . . , t1, t2, . . . , T1, T2, T3, and the like used for expressing any certain voltages, certain timings, certain temperatures, and the like in the present specification are not used to express absolute values, but are relative values used to be distinguishable from each other.

Various example embodiments will now be described more fully with reference to the accompanying drawings in which some example embodiments are shown. The present invention may, however, be embodied in different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure is thorough and complete and fully conveys the scope of the present invention to one skilled in the art. Also, since terms are defined in consideration of functions of the present invention, they may vary according to users' intentions or practice. Hence, the terms should not be interpreted as limiting technical components of the present invention.

Embodiment 1

FIG. 1 is a circuit diagram of an illumination apparatus using a semiconductor LED according to a first example embodiment of the present invention.

FIG. 1 illustrates an example of the illumination apparatus that adopts four LEDs L1 to L4. However, the present invention is not limited by the number of LEDs, and it would be apparent to those skilled in the art that the illumination apparatus of FIG. 1 may be modified into an illumination apparatus according to another example embodiment that uses at least two LEDs connected in series or an LED including a plurality of light emitting chips connected in series or parallel.

As shown in FIG. 1, an illumination apparatus using a semiconductor LED according to an example embodiment of the present invention may include a rectifier 100, a control signal generator 110, a switching unit 120, a current controller 130, a total current controller 140, and a light emitting unit 150.

The rectifier 100 may rectify an AC voltage VAC having positive and negative values and convert the rectified AC voltage into a driving voltage Vin in the form of a rectifying current voltage. One of various known rectifier circuits, such as a diode bridge circuit including diodes, may be adopted as the rectifier 100.

The control signal generator 110 may receive the driving voltage Vin, generate switch control signals SW1 to SW3 for controlling on/off operations of the switch unit 120, generate current control signals SC1 to SC4 for controlling operations of the current controller 130, and generate sampling signals COM0 to COM3 for determining a target voltage Vt, which is an output of the total current controller 140.

The switch unit 120 may include a plurality of switches 121, 122, and 123 connected in parallel to one another, and perform on/off operations in response to the switch control signals SW1 to SW3. Thus, the driving voltage Vin may be selectively applied to the LEDs L2 to L4.

The current controller 130 may be connected to a cathode terminal of each of the LEDs L1 to L4 and control operations of the connected LEDs in response to the current control signals SC1 to SC4. Also, the target voltage Vt may be applied to the current controller 130. Current amounts of the LEDs L1 to L4 connected to the current controller 130 may be determined according to the applied target voltage Vt.

To this end, the current controller 130 may include a plurality of driving current controllers 131, 132, 133, and 134. The driving current controllers 131, 132, 133, and 134 may be connected in parallel to one another.

For example, the first driving current controller 131 may receive a current control signal SC1 and a target voltage Vt. The first driving current controller 131 may be enabled or disabled in response to the current control signal SC1. When enabled, the first driving current controller 131 may allow a driving current corresponding to the target voltage Vt to flow through the LED L1.

The total current controller 140 may receive sampling signals COM0 to COM3 of the control signal generator 110 and convert the sampling signals COM0 to COM3 into analog signals. The converted analog signals may be applied in the form of the target voltage Vt to the current controller 130.

The light emitting unit 150 may include a plurality of LEDs L1 to L4 and a plurality of diodes D1 to D3. For example, the LED L1 may be connected between the driving voltage Vin and the first driving current controller 131. Also, the remaining LEDs L2 to L4 may be connected between the switch unit 120 and the driving current controllers 132, 133, and 134. For instance, the LED L1 may be expressed as a first light emitting group, and the remaining LEDs L2 to L4 may be expressed as a second light emitting group. The first light emitting group may be directly connected to the driving voltage Vin and perform a light emitting operation. Conversely, the second light emitting group may receive the driving voltage Vin only when each of the switches 121, 122, and 123 of the switch unit 120 is in a conduction state.

FIG. 2 is a circuit diagram of the control signal generator of FIG. 1.

Referring to FIG. 2, the control signal generator may include a comparison unit 112 and a logic combination unit 114.

The comparison unit 112 may receive the driving voltage Vin output from the rectifier 100 and compare the driving voltage Vin with a reference voltage VF. A comparison result may be indicated by levels of the sampling signals COM0 to COM3. To this end, the comparison unit 112 may include a plurality of voltage division resistors Rs1 to Rs5 connected in series between the driving voltage Vin and ground. Also, branches from nodes between the voltage division resistors Rs1 to Rs5 may be applied to the comparators 1121 to 1124. Voltages of the nodes between the voltage division resistors Rs1 to Rs5 may be applied to positive input terminals of the comparators 1121 to 1124, and the reference voltage VF may be applied in common to negative input terminals of the comparators 1121 to 1124.

When the voltages of the nodes between the voltage division resistors Rs1 to Rs5 applied to the positive input terminals of the respective comparators 1121 to 1124 are higher than the reference voltage VF applied to the negative input terminals thereof, the comparators 1121 to 1124 may output high-level signals. Also, when the voltages of the nodes between the voltage division resistors Rs1 to Rs5 applied to the positive input terminals of the respective comparators 1121 to 1124 are lower than the reference voltage VF applied to the negative input terminals thereof, the comparators 1121 to 1124 may output low-level signals.

The logic combination unit 114 may include a first logic unit 115 and a second logic unit 116.

The first logic unit 115 may receive the sampling signals COM0 to COM3 output by the respective comparators 1121 to 1124, perform logic combination operations on the sampling signals COM0 to COM3, and generate current control signals SC1 to SC4. The current control signals SC1 to SC4 may control operations of the current controller 130 of FIG. 1. The first logic unit 115 may include a combination of various logic devices according to signals of inputs and outputs. Also, a selection signal SEL may be applied to the first logic unit 115. The selection signal SEL may select a sampling signal on which a logic operation will be performed.

The second logic unit 116 may receive the sampling signals COM0 to COM3, perform logic combination operations on the sampling signals COM0 to COM3, and generate switch control signals SW1 to SW3. Each of the switch control signals SW1 to SW3 may control the switch unit 120 of FIG. 1. The second logic unit 116 may include a combination of various logic devices according to signals of inputs and outputs. Also, the selection signal SEL may be applied to the second logic unit 116. The selection signal SEL may select a predetermined sampling signal on which a logic operation will be performed.

Each of the first logic unit 115 and the second logic unit 116 may include a combination of logic devices, which may be variously selected according to phases of the input sampling signals COM0 to COM3 and phases of the switch control signals SW1 to SW3 or current control signals SC1 to SC4. For example, each of the two logic units 115 and 116 may include a programmable logic array or programmable array logic.

Also, the number of sampling signals may not be specifically limited but may be variously selected according to the number of output switch control signals and the number of current control signals.

FIG. 3 is a circuit diagram of respective components of the current controller of FIG. 1.

The circuit diagram of FIG. 3 illustrates any one of four driving current controllers constituting the current controller.

Referring to FIG. 3, the driving current controller may include a linear amplifier 1301, a buffer 1302, a driving transistor Qd, and a detection resistor Rd.

A voltage detected by the detection resistor Rd may be applied to a negative input terminal of the linear amplifier 1301. Also, the target voltage Vt may be applied to a positive input terminal of the linear amplifier 1301. The target voltage Vt may be a voltage generated by the total current controller 140 of FIG. 1. An output of the linear amplifier 1301 may be applied to the buffer 1302. The buffer 1302 may be enabled or disabled in response to the current control signals SC0 to SC3.

The term “enabling” refers to performing, by a target element, an input/output (I/O) function. Also, the term “disabling” refers to entering, by a target element, an off state or floated state without performing functions. Accordingly, during a disabling mode, the processing or transmission of signals may not occur. Hereinafter, the meanings of enabling and disabling in the present invention should be interpreted as described above.

The enabled buffer 1302 may transmit the output of the linear amplifier 1301 to the drive transistor Qd. The drive transistor Qd may be connected between the cathode terminal of each of the LEDs L1 to L4 and the detection resistor Rd. Also, the drive transistor Qd may perform on/off operations in response to the output of the buffer 1302 applied to a gate terminal thereof. The buffer 1302 may be any device configured to be capable of on/off operations in response to the current control signal SC. Accordingly, the buffer 1302 may be replaced by a switch.

When the buffer 1302 is enabled, a negative feedback including the drive transistor Qd, the linear amplifier 1301, and the buffer 1302 may be formed. When a detection voltage of the detection resistor Rd is lower than the target voltage Vt, the linear amplifier 1301 may output a high-level signal, which may be applied through the buffer 1302 to the gate terminal of the drive transistor Qd. A gate-source voltage Vgs of the drive transistor Qd may increase due to the increased voltage level. Thus, the amount of current flowing through the detection resistor Rd may increase. A detection voltage of the detection resistor Rd may increase due to the increased amount of current. That is, the detection voltage of the detection resistor Rd may be characterized by following the target voltage Vt.

When the buffer 1302 is disabled, the buffer 1302 may output a low-level signal or enter a floated state so that the drive transistor Qd may enter an off state.

As a result, no current may be supplied to the driving current controller.

FIG. 4 is a block diagram of the total current controller 140 of FIG. 1.

Referring to FIG. 4, the total current controller 140 may include a digital-to-analog converter (DAC) 141 configured to receive the sampling signals COM0 to COM3 generated by the control signal generator 110 shown in FIG. 2 and output a predetermined target value according to a state of each of the sampling signals COM0 to COM3. For example, the DAC 141 may receive logic values 0000 to 1111 of the sampling signals COM0 to COM3 and output a voltage corresponding to the predetermined target value in response to each of the logic values 0000 to 1111. The target voltage Vt corresponding to the target value may be input through the buffer 143 to the linear amplifier 1301 of each of the driving current controllers 131, 132, 133, and 134.

In addition, although FIG. 4 illustrates that the total current controller 140 outputs only one output, this is only an example. Thus, the total current controller 140 may output a plurality of outputs corresponding to the number of driving current controllers to which the target voltages Vt are applied. Also, a plurality of output target voltages Vt may have different values.

Also, the selection signal SEL may be input to the total current controller 140. When the selection signal SEL is enabled, the total current controller 140 may output different target voltages Vt.

FIG. 5 is a graph illustrating operations of the illumination apparatus of FIG. 1, according to the first example embodiment of the present invention.

Referring to FIG. 5, a driving voltage Vin, a magnitude of the total current IT flowing through all the LEDs, and a magnitude of current IL flowing through each of the LEDs are shown.

One cycle of the driving voltage Vin in the form of a rectifying current voltage is shown. Here, the driving voltage Vin periodically increases and decreases between 0V and a peak voltage. As shown in FIG. 5, the sum of currents flowing through all the LEDs L1 to L4, that is, the magnitude of the total current IT, may be controlled to be constant.

The switch unit 120 and the current controller 130 may be controlled as shown in Table 1.

TABLE 1 First Second Third Fourth driving driving driving driving current current current current First Second Third controller controller controller controller switch switch switch 131 132 133 134 121 122 123 VF ≦ Vin < 2VF ON ON ON ON ON ON ON 2VF ≦ Vin < 3VF OFF ON OFF ON OFF ON OFF 3VF ≦ Vin < 4VF OFF OFF ON OFF OFF OFF OFF OFF OFF ON ON ON OFF OFF 4VF ≦ Vin OFF OFF OFF ON OFF OFF OFF

Operations shown in Table 1 according to the first embodiment will be described with reference to FIGS. 1 through 3.

For brevity, it is assumed in FIG. 2 that the resistor Rs5 is removed or has an immaterial value. Accordingly, it is assumed that the driving voltage Vin is applied to the comparator 1124 without causing a drop in the level of the driving voltage Vin.

When the driving voltage Vin output by the rectifier 100 gradually increases from 0 V to a value equal to or higher than the reference voltage VF and lower than 2VF, the sampling signal COM3 output by the comparator 1124 may become a high-level signal. Sampling signals output by the remaining comparators 1121, 1122, and 1123 may become low-level signals. The reference voltage VF may be a forward voltage by which each LED L1 or L4 may initiate a light emitting operation.

The first logic unit 115 receiving the output of the comparison unit 112 may enable all the current control signals SC1 to SC4. Also, the second logic unit 116 may enable all the switch control signals SW1 to SW3. Thus, all the switches 121, 122, and 123 of the switch unit 120 may be turned on, while all the driving current controllers 131, 132, 133, and 134 may be enabled.

That is, in FIG. 2, the sampling signals COM0 to COM3 may be input in the form of (0001) to the first logic unit 115 and the second logic unit 116. The first logic unit 115 receiving the sampling signals COM0 to COM3 d may enable all the current control signals SC1 to SC4. For example, all the current control signals SC1 to SC4 may be enabled to a high level. Also, the second logic unit 116 may enable the switch control signals SW1 to SW3. Accordingly, the first through third switches 121 to 123 may be turned on. All the LEDs L1 to L4 may be connected in parallel by the turned-on switches 121, 122, and 123 and the enabled driving current controllers 131, 132, 133, and 134.

In addition, the DAC 141 of the total current controller 140 may receive a logic signal (e.g., 0001) of the sampling signals COM0 to COM3 output by the comparison unit 112 of the control signal generator 110 and generate the target voltage Vt corresponding to the predetermined target value in response to the logic signal. In this case, the target value may be a value equal to ¼ the total current IT so as to constantly control the total current IT.

Due to the above-described operation, all the driving current controllers 131, 132, 133, and 134 and the switches 121, 122, and 123 may be put into a conduction state or enabled, and the plurality of LEDs L1 to L4 may be electrically connected in parallel to one another due to states of the driving current controllers 131, 132, 133, and 134 and the switches 121, 122, and 123. As a result, the total driving current IT may be divided by four and supplied to the respective LEDs L1 to L4.

To sum up, when the driving voltage Vin is equal to or higher than the reference voltage VF, high-level current control signals SC1 to SC4 may be applied from the control signal generator 110 to the buffers 1302 of the respective driving current controllers 131, 132, 133, and 134, and the target voltage Vt corresponding to a target value equal to ¼ the total driving current IT may be applied from the total current controller 140 to the linear amplifiers 1301 of the respective driving current controllers 131, 132, 133, and 134. Thus, the linear amplifier 1301 may adjust a gate voltage of the driving transistor Qd such that a voltage applied to the detection resistor Rd is equal to the target voltage Vt so that current corresponding to ¼ the total driving current IT may flow between source and drain terminals of the driving transistor Qd. As a result, current IL corresponding to ¼ the total driving current IT may be divided and supplied to each of the LEDs L1 to L4.

When the magnitude of the driving voltage Vin output by the rectifier 100 gradually increases to a value higher than or equal to 2VF, and lower than 3VF, the control signal generator 110 may generate and output a switch control signal by which two of the LEDs L1 to L4 may be connected in series. That is, the two comparators 1123 and 1124 of FIG. 2 may output high-level signals.

The sampling signals COM0 to COM3 output by the comparators 1121 to 1124 may be output in the form of (0011).

In addition, the first logic unit 115 receiving the sampling signals COM0 to COM3 may enable the current control signals SC2 to SC4.

Accordingly, current flowing through the LED L2 may be supplied to the second driving current controller 132, and current supplied to the LED L4 may be supplied to the fourth driving current controller 134.

In addition, the second logic unit 116 receiving the sampling signals COM0 to COM3 may enable the switch control signal SW2. Accordingly, the second switch 122 may be turned on, while the remaining switches 121 and 123 may be turned off.

The total current controller 140 may receive the sampling signals COM0 to COM3 in the form of (0011). The input sampling signals COM0 to COM3 may be converted into analog signals and output as a target voltage Vt. The target voltage Vt may allow the driving current IL of the enabled driving current controllers 142 and 144 to be ½ the total current IT.

Due to the operations of the switch unit 120 and the current controller 130, the second switch 122 may be turned on, and the second driving current controller 142 and the fourth driving current controller 144 may be enabled. Thus, a current path including the LED L1, the diode D1, the LED L2, and the second driving current controller 142 may be formed, and another current path including the LED L3, the diode D3, the LED L4, and the fourth driving current controller 144 may be formed.

As a result, the total driving current IT may be halved and supplied to the respective current paths.

When the driving voltage Vin output by the rectifier 100 is higher than or equal to 3VF, and lower than 4VF, the control signal generator 110 may generate switch control signals SW1 to SW3 by which three of the LEDs L1 to L4 may be connected in series, and output current control signals SC1 to SC4.

The sampling signals COM0 to COM3 output by the comparison unit 112 of the control signal generator 110 may be output in the form of (0111). This means that the sampling signal COM0 is a low-level signal, and the remaining sampling signals COM1 to COM3 are high-level signals.

The first logic unit 115 receiving the sampling signals COM0 to COM3 may enable the current control signal SC3. Thus, only the third driving current controller 133 may be enabled and the remaining driving current controllers 131, 132, and 134 disabled.

Also, the second logic unit 116 receiving the sampling signals COM0 to COM3 may disable all the switch control signals SW1 to SW3. Accordingly, all the switches 121, 122, and 123 of the switch unit 120 may be turned off.

Thus, a current path including the LED L1, the diode D1, the LED L2, the diode D2, the LED D3, and the third driving current controller 133 may be formed. Accordingly, three LEDs L1, L2, and L3 of FIG. 1 may perform light emitting operations.

Furthermore, the total current controller 140 may receive the sampling signals COM0 to COM3 and convert the sampling signals COM0 to COM3 into the target voltages Vt. That is, the total current controller 140 may receive the logic signal (0111) and generate the target voltage Vt in response to the logic signal (0111). Since only the three LEDs L1, L2, and L3 connected in series are operated in response to the generated target voltage Vt, a level of the generated target voltage Vt may have a value corresponding to the total current.

In addition, the LED L4, which is not connected in series to the LEDs L1, L2, and L3, may selectively emit light. To this end, an externally input selection signal SEL may be applied to the first and second logic units 115 and 116 of the control signal generator 110. When the selection signal SEL is enabled, the first logic unit 115 may enable the current control signals SC3 and SC4. Thus, the third driving current controller 133 and the fourth driving current controller 134 may be enabled. Also, the second logic unit 116 may receive the enabled selection signal SEL, perform a logic operation on the enabled selection signal SE, and enable the switch control signal SW1. Accordingly, the first switch 121 may be turned on.

Thus, a current path including the LED L1, the diode D1, the LED L2, the diode D2, the LED L3, and the third driving current controller 133 may be formed, and another current path including the LED L4 and the fourth driving current controller 134 may be formed.

In addition, the selection signal SEL may be applied to the total current controller 140. The DAC 141 constituting the total controller 140 may receive the selection signal SEL in addition to the sampling signals COM0 to COM3 of the control signal generator 110. When the selection signal SEL is enabled, the total current controller 140 may generate two kinds of target voltages. For instance, the total current controller 140 may process the sampling signals COM0 to COM3 to generate a target voltage Vt1 applied to the third driving current controller 133, and generate a target voltage Vt2 applied to the fourth driving current controller 134 sing the sampling signals COM0 to COM3 and the selection signal SEL.

The target voltage Vt1 applied to the third driving current controller 133 may be set as a value corresponding to ¾ the total driving current IT, and the target voltage Vt2 applied to the fourth driving current controller 134 may be set as a value corresponding to ¼ the total driving current IT.

When the driving voltage Vin, which is an output voltage of the rectifier 100, is at least 4 times the reference voltage VF, all the comparators 1121 to 1124 of the control signal generator 110 may generate high-level signals. Accordingly, the sampling signals COM0 to COM3 may have a logic value (1111).

The first logic unit 115 receiving the sampling signals COM0 to COM3 may enable the current control signal SC4.

Thus, the fourth driving current controller 134 may be enabled. Also, the second logic unit 116 receiving the sampling signals COM0 to COM3 may disable all switch control signals. Accordingly, all the switches 121, 122, and 123 of the switch unit 120 may be turned off.

Accordingly, in FIG. 1, a current path including the LED L1, the diode D1, the LED L2, the diode D2, the LED L3, the diode D3, the LED L4, and the fourth driving current controller 134 may be formed.

Also, the total current controller 140 may receive the sampling signals COM0 to COM3 output by the comparison unit 112 of the control signal generator 110 and convert the sampling signals COM0 to COM3 into a target voltage Vt, which is an analog signal. The target voltage Vt may be applied to the fourth driving current controller 134, which may drive current corresponding to the total current driving current IT.

Referring to FIG. 5, the magnitude of the total current IT may be controlled to be constant in the form of one square wave. Even if the driving voltage Vin varies, the total current IT may be appropriately divided and supplied to respective LEDs. Current flowing through each of the LEDs may vary according to a level of the driving voltage Vin. In the above-described case, the average amounts of power supplied to the respective LEDs may be equalized, and a power factor and critical conditions may be satisfied.

FIG. 6 is another graph illustrating operations of the illumination apparatus of FIG. 1, according to the first example embodiment of the present invention.

Referring to FIG. 6, a driving voltage Vin, a magnitude of the total current IT flowing through all the LEDs, and a magnitude of current IL flowing through each of the LEDs are shown.

Although the operations described with reference to FIG. 5 are characterized by constantly controlling the magnitude of the total current IT, in FIG. 6, even if switching conditions are changed, the magnitude of current IL flowing through each of the LEDs is controlled to be constant to maintain a constant light emitting amount.

Since the switching conditions are the same as in Table 1, a description thereof will be omitted. Also, an equal amount of current flows through each of the LEDs, a process of generating the target voltage Vt using sampling signals may be omitted. Accordingly, in addition to generation of the target voltage Vt using the total current controller 140, the target voltage Vt may be applied to the respective driving current controllers 131, 132, 133, and 134 using an additional supply voltage.

To begin with, when the driving voltage Vin output by the rectifier 100 gradually increases from 0V to a value equal to or higher than the reference voltage VF and lower than 2VF, the four LEDs L1 to L4 may be connected in parallel to one another.

In this case, the total current controller 140 may supply the target voltage Vt such that a predetermined reference current Iref is supplied to each of the driving current controllers 131, 132, 133, and 134. Thus, the reference current Iref may flow through each of the LEDs, and the total current amount may become 4Iref.

Subsequently, when the driving voltage Vin output by the rectifier 100 reaches a value equal to or higher than 2VF and lower than 3VF, an array including two LEDs L1 and L2 connected in series and an array including two LEDs L3 and L4 connected in series may be connected in parallel to each other. In this case, the total current controller 140 may supply the target voltage Vt to the second driving current controller 132 and the fourth driving current controller 134. Thus, the reference current Iref may flow through the LEDs L1 and L2 connected in series and also flow through the LEDs L3 and L4 connected in series. Accordingly, the total current amount may become 2Iref.

Thereafter, when the driving voltage Vin output by the rectifier 100 reaches a value equal to or higher than 3VF, and lower than 4VF, an array including three LEDs L1 to L3 connected in series may be connected in parallel to one LED L4. The total current controller 140 may supply the target voltage Vt to the third driving current controller 133 and the fourth driving current controller 134. Each of the driving current controllers 133 and 134 may drive the reference current Iref. Accordingly, the total current amount may become 2Iref.

Thereafter, when the magnitude of the driving voltage Vin output by the rectifier 100 is 4VF or higher, all the LEDs L1 to L4 may be connected in series. The total current controller 140 may supply the target voltage Vt to the fourth driving current controller 134. According, the total current amount may become Iref.

As shown in FIG. 6, the total current IT may vary according to the magnitude of the driving voltage Vin. Also, current flowing through one LED may be always controlled to be constant. In this case, the average amounts of power supplied to the respective LEDs may differ from one another. However, even if a connection relationship among the respective LEDs is changed, since light emitting amounts of the respective LEDs are always maintained constant, the illumination apparatus can maintain constant brightness.

Embodiment 2

FIG. 7 is a circuit diagram of an illumination apparatus using a semiconductor LED according to a second example embodiment of the present invention.

FIG. 7 illustrates an example of the illumination apparatus that adopts four LEDs. However, the present invention is not limited by the number of LEDs, and each of the LEDs may be one LED obtained by modeling a serial connection structure of at least two LEDs, a parallel connection structure of at least two LEDs, or a mixture of serial and parallel connection structures.

In addition, the illumination apparatus according to the present embodiment may include a rectifier 200, a control signal generator 210, a switch unit 220, a current controller 230, a total current controller 240, and a light emitting unit 250.

The rectifier 200 may rectify an AC voltage having positive and negative values and convert the AC voltage into a driving voltage Vin in the form of a rectifying current voltage. One of various known rectifier circuits, such as a diode bridge circuit including diodes, may be adopted as the rectifier 200.

The control signal generator 210 may detect the driving voltage Vin and generate sampling signals COM0 to COM1, switch control signals SW1 to SW3, and current control signals SC1 to SC4 according to the magnitude of the detected driving voltage Vin. The sampling signals COM0 to COM3 may be applied to the total current controller 240, and the switch control signals SW1 to SW3 may be applied to the switch unit 220. Also, the current control signals SC1 to SC4 may be respectively applied to driving current controllers 231 to 234 of the current controller 230.

The switch unit 220 may be provided between the driving voltage Vin and the light emitting unit 250. Also, the switch unit 220 may include a plurality of switches, each of which may have a short circuit or be opened in response to the switch control signals SW1 to SW3.

The current controller 230 may include a plurality of driving current controllers 231, 232, 233, and 234. The driving current controllers 231, 232, 233, and 234 may be respectively connected to cathode terminals of the LEDs L21, L22, L23, and L24. The current control signals SC1 to SC4 may be applied to the driving current controllers 231, 232, 233, and 234. The driving current controllers 231, 232, 233, and 234 may be enabled or disabled in response to the applied current control signals SC1 to SC4.

For example, when the current control signals SC1 to SC4 are enabled to a high level, the driving current controllers 231, 232, 233, and 234 may have predetermined current drivability and perform operations. Conversely, when the current control signals SC1 to SC4 are disabled to a low level, the driving current controllers 231, 232, 233, and 234 may be put into a high-impedance state or floated state and may not perform current drive operations. Also, the target voltages Vt1 to Vt4 may be applied to the driving current controllers 231, 232, 233, and 234. When the driving current controllers 231, 232, 233, and 234 remain enabled, the target voltages Vt1 to Vt4 may determine the amount of current by which the illumination apparatus is driven.

The driving current controllers 231 to 234 constituting the current controller 230 may be the same as described in the first embodiment. Thus, a description thereof will be omitted here.

Accordingly, when the current control signals SC1 to SC4 are enabled, a buffer may be enabled and receive the output of an amplifier. The output of the amplifier may change a gate-source voltage Vgs of a transistor via the buffer. The changed gate-source voltage Vgs may vary a driving current. The varied driving current may flow through a detection resistor, and a voltage detected by the detection resistor may be applied to a negative input terminal of the amplifier. The voltage detected by the detection resistor may be characterized by following a target voltage applied to a positive input terminal of the amplifier.

Therefore, as the target voltage increases, a driving current set by each of the driving current controllers 231 to 234 may also increase.

The total current controller 240 may receive sampling signals COM0 to COM3 of the control signal generator 210. The sampling signals COM0 to COM3 may be input in the form of digital data. Accordingly, the total current controller 240 may perform DAC operations and generate target voltages Vt1 to Vt4. The target voltages Vt1 to Vt4 may be respectively input to the driving current controllers 231, 232, 233, and 234. The target voltages Vt1 to Vt4 may have the same value or different values.

The light emitting unit 250 may include a first LED L21, a second LED L22, a third LED L23, and a fourth LED L24. Also, the light emitting unit 250 may be connected between the switch unit 220 and the current controller 230. Cathode electrodes of the LEDs L21, L22, L23, and L24 may be respectively connected to the driving current controllers 231, 232, 233, and 234. Also, diodes D21, D22, and D23 may be connected among the LEDs L21, L22, L23, and L24. The diodes D21, D22, and D23 may have a forward connection relationship among the LEDs L21, L22, L23, and L24. For example, when the first LED L21 and the second LED L22 are electrically connected in series, the diode D21 connected between the two LEDs L21 and L22 may supply current from the first LED L21 to the second LED L22 through a forward connection structure. Also, the diodes D21, D22, D23, and D24 may be connected in a reverse direction in a current path from the switch unit 220 toward the current controller 230. As a result, direct application of the driving voltage Vin through the switch unit 220 to the current controller 230 may be prevented.

FIG. 8 is a circuit diagram of the control signal generator 210 according to the second example embodiment of the present invention.

Referring to FIG. 8, the control signal generator 210 may include a comparison unit 211 and a logic combination unit 212.

The comparison unit 211 may include a plurality of comparators 2110 to 2115. A reference voltage VF may be applied to a negative input terminal of each of the comparators 2110 to 2115, and a voltage obtained by dividing the driving voltage Vin by a resistor may be applied to a positive input terminal thereof. Thus, two resistors may be connected in series to each path, and a voltage detected at a node between resistors may be input to the positive input terminal of each of the comparators 2110 to 2115.

The comparators 2110 to 2115 may perform comparison operations and generate sampling signals COM0 to COM5.

For instance, when resistors R21 to R26 obey the relationship R26>R25>R24>R23>R22>R21, and a resistor Rref connected to the driving voltage Vin has a predetermined resistance which is the same for each path, the output sampling signals COM0 to COM5 may be changed from (000000) to (111111) with a rise in the driving voltage Vin.

In addition, the comparison unit 211 according to the present embodiment may be replaced by the comparison unit 112 according to the first embodiment. The number of serial resistors of the comparison unit 112 according to the first embodiment and the number of comparators may vary according to the number of output sampling signals.

The sampling signals COM0 to COM5 output by the comparison unit 211 may be supplied to the total current controller 240 and supplied to the logic combination unit 212.

The logic combination unit 212 may receive the sampling signals COM0 to COM5 output by the comparison unit 211 and perform logic operations on the sampling signals COM1 to COM5. As a result, the switch control signals SW1 to SW3 and the current control signals SC1 to SC4 may be generated.

The logic combination unit 212 may include a combination of logic devices that may be variously selected according to phases of the input sampling signals COM0 to COM5 and phases of output switch control signals SW1 to SW3 or current control signals SC1 to SC4. For example, the logic combination unit 212 may include a programmable logic array or programmable array logic.

Also, the number of sampling signals may not be specifically limited but may be variously selected according to the number of output switch control signals and the number of current control signals.

FIG. 9 is a circuit diagram of the switch unit 220 according to the second example embodiment of the present invention.

Referring to FIG. 9, the switch unit 220 may include three switches 221, 222, and 223, and each of the switch units 221, 222, and 223 may include switches QW1 to QW3 and control transistors QS1 to QS3.

Each of the switch transistors QW1 to QW3 and the control transistors QS1 to QS3 may be a metal-oxide-semiconductor field effect transistor (MOSFET) and selectively have an n conductivity type or a p conductivity type. When each of the switch transistors QW1 to QW3 is an n-MOSFET, a drain terminal of the n-MOSFET may be connected to the driving voltage Vin, and resistors RZ1 to RZ3 may be connected between drain and gate terminals of the switch transistors QW1 to QW3. Also, zener diodes DZ1 to DZ3 may be provided between gate and source terminals of the switch transistors QW1 to QW3. When a surge voltage, which is a sudden high voltage, is applied to gate terminals of the zener diodes DZ1 to DZ3, the zener diodes DZ1 to DZ3 may be clipped to a constant level. Also, the switch transistors QW1 to QW3 may perform switch operations using the resistors RZ1 to RZ3 connected between the gate and drain terminals of the switch transistors QW1 to QW3 with the control transistors QS1 to QS3 cut off.

The control transistors QS1 to QS3 may be respectively connected between gate terminals of the switch transistors QW1 to QW3 and ground, and the switch control signals SW1 to SW3 may be applied to the gate terminals of the control transistors QS1 to QS3.

When the switch control signals SW1 to SW3 are enabled to a high level, the control transistors QS1 to QS3 may be turned on. Thus, the gate terminals of the switch transistors QW1 to QW3 may be disabled to a low level. Accordingly, the switch transistors QW1 to QW3 may be turned off.

When the switch control signals SW1 to SW3 are disabled to a low level, the control transistors QS1 to QS3 may be turned off. Also, a voltage having a predetermined level may be applied to the switch transistors QW1 to QW3 due to resistors RZ1 to RZ3 connected between gate and drain terminals of the switch transistors QW1 to QW3. In particular, a current path including the driving voltage Vin and the resistors RZ1 to RZ3 may be cut off due to the cut-off control transistors QS1 to QS3. Thus, a voltage having substantially the same level as the driving voltage Vin may be applied to the gate terminals of the switch transistors QW1 to QW3. Accordingly, the switch transistors QW1 to QW3 of the switch unit 220 may be turned on.

For brevity, when a level of a switch control signal appropriate for turning on a switch transistor is applied, the switch control signal may be described as being enabled. Also, when a switch control signal appropriate for turning on the switch transistor is applied, the switch control signal may be described as being disabled.

When the switches 221, 222, and 223 are turned on, the driving voltage Vin may be applied to the LEDs L21, L22, L23, and L24 through the nodes N1, N2, and N3.

In addition, an operation of the illumination apparatus according to the present embodiment will be described with reference to Table 2.

TABLE 2 First Second Third Fourth driving driving driving driving current current current current First Second Third controller controller controller controller switch switch switch 231 232 233 234 221 222 223 VF ≦ Vin < 2VF ON ON ON ON ON OFF OFF ON ON ON ON ON ON OFF 2VF ≦ Vin < 3VF OFF ON OFF ON OFF ON OFF 3VF ≦ Vin OFF OFF OFF ON OFF OFF ON

Table 2 shows an example of the operation of the illumination apparatus of FIG. 7.

Initially, the switch control signal SW1 may be enabled, and the remaining switch control signals may be disabled. Thus, only the switch transistor QW1 may be turned on, and the first switch 221 may go into a conduction state. The driving voltage Vin may be applied through the switch transistor QW1 to the first node N1.

Also, the first through fourth driving current controller 231 through 234 may be enabled in response to the applied current control signals SC1 to SC4. In addition, the target voltages Vt1 to Vt4 may be applied by the total current controller 240 to the first through fourth driving current controllers 231 to 234. The target voltages Vt1 to Vt4 may have the same value.

Accordingly, a current path including the first node N1, the first LED L21, and the first driving current controller 231 may be formed due to the turned-on first switch 221, and the first LED L21 may perform a light emitting operation. Also, a current path including the first node N1, the second LED L22, and the second driving current controller 232 may be formed, a current path including the first node N1, the third LED L23, and the third driving current controller 233 may be formed, and a current path including the first node N1, the fourth LED L24, and the fourth driving current controller 234 may be formed. This means that the respective LEDs L21 to L24 are connected in parallel to one another and perform light emitting operations.

Furthermore, additional diodes may be provided between the respective nodes and the LEDs L21 to L24 to cut off the flow of a backward current between anode terminals and cathode terminals of the LEDs.

When the switch control signals SW1 and SW2 are enabled, the first switch 221 and the second switch 222 may be turned on. Thus, a driving voltage Vin may be applied to a first node N1 through the turned-on first switch 221, and the driving voltage Vin may be applied to a second node N2 through the turned-on second switch 222. Also, the enabled current control signals SC1 to SC4 may be applied to the first through fourth driving current controllers 231 to 234. Thus, the first through fourth driving current controllers 231 to 234 may be enabled. Also, target voltages Vt1 to Vt4 may be respectively applied to the driving current controllers 231 to 234. The target voltages Vt1 to Vt4 may have the same value.

Accordingly, a current path including the LED L21 and the first driving current controller 231 may be formed. The driving voltage Vin may be applied from the first node N1 to the current path, and the driving voltage Vin may be applied from the second node N2 to the current path. Also, a current path including the LED L22 and the second driving current controller 232 may be formed. Furthermore, the LED L23 may receive the driving voltage Vin from the first node N1 and receive the driving voltage Vin from the second node N2. Also, the LED L24 may receive the driving voltage Vin from the first node N1.

Accordingly, when the switch control signals SW1 and SW2 are enabled and the respective driving current controllers 231 to 234 are enabled, the respective LEDs L21 to L24 may perform parallel light emitting operations. This means that the LEDs L21 to L24 are not affected by light emitting operations of other adjacent LEDs but independently perform light emitting operations at the same time.

Diodes D21 to D23 may be provided among the LEDs L21 to L24. The diodes D21 to D23 may be provided to cut off the flow of a backward current when a reverse bias is applied between anode terminals and cathode terminals of adjacent LEDs.

When the switch control signal SW2 is enabled, the second switch 222 may be turned on. Thus, the driving voltage Vin may be applied to the second node N2.

Also, the current control signals SC2 and SC4 may be enabled. Thus, the second driving current controller 232 and the fourth driving current controller 234 may be enabled. The target voltages Vt2 and Vt4 may be applied to the enabled driving current controllers 232 and 234. The applied target voltages Vt2 and Vt4 may have the same value.

A current path including the second node N2, the LED L21, the diode D21, the LED L22, and the second driving current controller 232 may be formed in response to the switch control signal SW2 and the current control signals SC2 and SC4. Also, the driving voltage Vin of the second node N2 may be applied to the current path, and the amount of current flowing through the current path may be determined by the target voltage Vt2 applied to the second driving current controller 232.

A current path including the LED L23, the diode D23, the LED L24, and the fourth driving current controller 234 may be formed parallel to the above-described current path. The driving voltage Vin of the second node N2 may be applied to the current path, and the amount of current flowing through the current path may be determined by the target voltage Vt4 applied to the fourth driving current controller 234.

The above-described operation may be enabled by a serial connection structure of two LEDs. Also, two serial connection structures may be provided and connected in parallel to each other.

In addition, when the switch control signal SW3 is enabled, the third switch 223 may be turned on. Thus, the driving voltage Vin may be applied to the third node N3 through the turned-on third switch 223.

Furthermore, the current control signal SC3 may be enabled and the remaining current control signals disabled. Thus, only the fourth driving current controller 234 may be enabled and perform a current drive operation. That is, a current path including the LED L21, the diode D21, the LED L22, the diode D22, the LED L23, the diode D23, the LED L24, and the fourth driving current controller 234 may be formed. The formed current path may include four LEDs connected in series. Current flowing through the current path may be determined by the target voltage Vt4 applied to the fourth driving current controller 234.

Due to the above-described operations, the LEDs can be directly and discretely driven by the driving current controller and connected in various forms to enable light emitting operations.

In the present embodiment, a target voltage determined by the total current controller can be applied to the driving current controller. The target voltage can determine the driving current of the driving current controller.

As described in the first embodiment with reference to FIGS. 5 and 6, the total current amount of the illumination apparatus can be set constant, and the currents flowing through respective current paths can be set constant. Therefore, power consumption can be appropriately divided, and the luminance of each of the LEDs can be controlled to be constant.

As explained thus far, in one embodiment of the present invention, an electrical connection relationship among a plurality of LEDs can be appropriately changed with fluctuations in the magnitude of an AC voltage for driving the plurality of LEDs so that all of the plurality of LEDs employed in the illumination apparatus can emit light. Thus, longer light emission by only some of the LEDs employed in the illumination apparatus, which leads to earlier deterioration of those LEDs compared to other LEDs, can be prevented.

In addition, when necessary, the total current supplied to all the LEDs can be controlled to be constant or current supplied to each of the LEDs can be controlled to be constant.

Embodiment 3

Meanwhile, the illumination apparatus using the semiconductor light emitting element according to the first example embodiment of the present invention described with reference to FIGS. 1 to 6 and the illumination apparatus using the semiconductor light emitting element according to the second example embodiment of the present invention described with reference to FIGS. 7 and 9 may be configured to perform a free voltage function, if necessary, even though a separate additional circuit for performing the free voltage function is not added.

Hereinafter, although an implementation example of the free voltage function according to the present invention (i.e., the illumination apparatus of the light emitting element according to the third example embodiment) will be described with reference to the illumination apparatus using the semiconductor light emitting element according to the first example embodiment of the present invention described with reference to FIGS. 1 to 6 for convenience of explanation and understanding, it should be noted that the same technical scope may be equally applied to other example embodiments of the present invention.

The same technical scope as the contents described above cites the above-mentioned description about the first example embodiment and the second example embodiment, and hereinafter, a configuration for implementing the free voltage function and a function thereof will be mainly described.

First, a key idea for implementing the free voltage function in the present invention is to detect a standard of the AC power to which the illumination apparatus of the light emitting element according to the third example embodiment is connected (i.e., an effective voltage value of the AC power input to the illumination apparatus of the light emitting element according to the third example embodiment) and to control a series and parallel connection relationship between a first light emitting group L31 to a fourth light emitting group L34 so as to ensure that the first light emitting group L31 to the fourth light emitting group L34 are smoothly driven under the detected standard of the AC power. For example, it is assumed that the light emitting unit configured to include the first light emitting group to the fourth light emitting group, as an illumination apparatus (not shown) of a sequential driving type of light emitting element according to the related art is configured to have the first forward voltage level VF1 of 50V, the second forward voltage level VF2 of 100V, the third forward voltage level of 150V, and the fourth forward voltage level VF4 of 200V. In this case, when the illumination apparatus of the light emitting element according the related art is connected to the AC power of 220V(rms) or 277V(rms), the first light emitting group to the fourth light emitting group may be all operated in a state in which the first light emitting group to the fourth light emitting group are connected in series with each other, but when the illumination apparatus of the light emitting element according the related art is connected to the AC power of 120V(rms), the first light emitting group to the fourth light emitting group may not be all operated in the state in which the first light emitting group to the fourth light emitting group are connected in series with each other. That is, according to the related art, in the case in which the illumination apparatus of the light emitting element is connected to the AC power of 120V(rms), there is a problem that the third light emitting group and the fourth light emitting group of the first light emitting group to the fourth light emitting group connected in series with each other are not continuously emitted. Similarly, according to the related art, in a state in which a first set of light emitting groups (the first light emitting group and the second light emitting group connected in series with each other) and a second set of light emitting groups (the third light emitting group and the fourth light emitting group connected in series with each other) are connected in parallel to each other, when the illumination apparatus of the light emitting element is connected to the AC power of 220V(rms) or 277V(rms), there is a problem that power efficiency is deteriorated.

In order to solve the problems as described above, the illumination apparatus of the light emitting element according to the third example embodiment of the present invention may be configured to detect an average voltage level per period of the driving voltage Vin and compare the detected average voltage level with a first average voltage reference level which is preset to determine a standard of the AC power to which the illumination apparatus is currently connected (i.e., the effective voltage level supplied by the connected AC power). More specifically, for example, the illumination apparatus of the light emitting element according to the third example embodiment of the present invention may accumulate the driving voltage Vin supplied during predetermined periods (e.g., 10 to 40 periods) and detect the average voltage level per period of the driving voltage Vin based on the accumulated driving voltage Vin.

That is, the AC power of 120V(rms) has the average voltage level per period of the driving voltage Vin of a specific value, the AC power of 220V(rms) has the average voltage level per period of the driving voltage Vin of another specific value, and the AC power of 277V(rms) has the average voltage level per period of the driving voltage Vin of still another specific value. Therefore, by detecting the average voltage level per period of a supplied rectified voltage, the standard of the AC power to which the illumination apparatus of the light emitting element according to the third example embodiment is connected may be determined. Specific numeric values mentioned above are merely illustrative, and various numeric values may be used, if necessary. For example, the AC power may also have effective voltages of 100V, 300V, and the like, and it will be apparent to those skilled in the art that the present invention may be applied to the above-mentioned all cases. In addition, although the example embodiment configured to determine the standard (effective voltage) of the AC power to which the illumination apparatus is currently connected, by detecting the average voltage level per period of the driving voltage Vin has been described above, it will be apparent to those skilled in the art that the above-mentioned principle may also be equally applied to the illumination apparatus of the light emitting element according to the third example embodiment configured to include a power factor compensator (not shown). That is, in the case in which the illumination apparatus of the light emitting element according to the third example embodiment is configured to include the power factor compensator, the illumination apparatus of the light emitting element according to the third example embodiment may be configured to determine performance of the AC power to which the illumination apparatus of the light emitting element according to the third example embodiment is connected, by detecting the average voltage level per period of a power factor compensated driving voltage Vin supplied to the light emitting unit 350. Hereinafter, for convenience of explanation and understanding, as shown in FIG. 10, the description will be provided based on an example embodiment in which the illumination apparatus of the light emitting element according to the third example embodiment does not include the power factor compensator and is configured to determine the standard of the AC power by detecting the average voltage level per period of the driving voltage Vin, but the present invention is not limited thereto.

Meanwhile, more preferably, according to an example embodiment, the illumination apparatus of the light emitting element according to the third example embodiment may be configured so as not to determine an exact standard of the AC power to which the illumination apparatus of the light emitting element according to the third example embodiment is connected, but to compare the average voltage level per period of the driving voltage Vin with the first average voltage reference level which is preset, and open and close the switch unit 120 depending on the comparison result. Here, the first average voltage reference level may be a value corresponding to a specific effective voltage of the AC power for controlling a series and parallel connection relationship of the first light emitting group L31 to the fourth light emitting group L34. That is, the illumination apparatus of the light emitting element according to the third example embodiment may be configured to only determine whether the effective voltage of the AC power to which the illumination apparatus of the light emitting element according to the third example embodiment is connected is large enough to drive the first light emitting group L31 to the fourth light emitting group L34 in a state in which the first light emitting group L31 to the fourth light emitting group L34 are connected in series with each other, or is small enough to drive the first light emitting group L31 to the fourth light emitting group L34 in a state in which the first light emitting group L31 to the fourth light emitting group L34 are divided into predetermined subsets so as to be connected in parallel to each other, and control the open and close of the switch unit 120 based on the above-mentioned determination. For example, in the example described above (in the case in which the light emitting unit 350 is configured to have the first forward voltage level VF1 of 50V, the second forward voltage level VF2 of 100V, the third forward voltage level VF3 of 150V, and the fourth forward voltage level VF4 of 200V), when the AC power to which the illumination apparatus is connected has the effective voltage of 220V or 277V, the AC power has the effective voltage which is large enough to drive the first light emitting group L31 to the fourth light emitting group L34 which are connected in series with each other, and on the other hand, when the AC power to which the illumination apparatus is connected has the effective voltage of 120V, the AC power has the effective voltage which is small enough to drive the first light emitting group L31 to the fourth light emitting group L34 in the state in which the first light emitting group L31 to the fourth light emitting group L34 are divided into predetermined subsets so as to be connected in parallel to each other. Therefore, according to an example embodiment, the illumination apparatus of the light emitting element according to the third example embodiment of the present invention may determine performance of the AC power to which the illumination apparatus is currently connected, by setting the first average voltage reference level so as to correspond to any reference effective voltage between 120V(rms) and 277V(rms) (e.g., 200V(rms)) and comparing the average voltage level per period of the driving voltage Vin with the first average voltage reference level which is preset. Of course, depending on the configuration of the example embodiment, two or more average voltage reference levels may also be used to determine standards of various AC powers. For example, the first average voltage reference level corresponding to 120V(rms), a second average voltage reference level corresponding to 220V(rms), and a third average voltage reference level corresponding to 277V(rms) may also be used.

In order to perform the function as described above, as shown in FIG. 10, the illumination apparatus of the light emitting element according to the third example embodiment of the present invention may include the rectifier 100, a control signal generator 310, the switch unit 120, a current controller 330, a total current controller 340, and the light emitting unit 350.

Since the configuration and the function of the rectifier 100, the switch unit 120, the current controller 330, the total current controller 340, and the light emitting unit 350 among the components as described above are substantially similar to the corresponding configurations of the first example embodiment and the second example embodiment described above, the overlapped descriptions are cited. Hereinafter, the present example embodiment will be described based on differences.

First, the light emitting unit 350 may be configured to include a plurality of light emitting groups, and the plurality of light emitting groups included in the light emitting unit 350 may be configured to control a series and parallel connection relationship therebetween according to a control of the control signal generator 310 and to be sequentially driven at the same time. Although FIG. 10 discloses the light emitting unit 350 including four light emitting groups from the first light emitting group L31 to the fourth light emitting group L34, it will be apparent to those skilled in the art that the number of light emitting groups included in the light emitting unit 350 may be variously changed, if necessary. However, hereinafter, the description will be provided based on an example embodiment in which the light emitting unit 350 includes the four light emitting groups for convenience of explanation and understanding, but the present invention is not limited thereto. For example, the light emitting unit 350 may also include n light emitting groups from the first light emitting group L31 to an n-th (n is a positive integer of two or more) light emitting group (not shown), and it will be apparent to those skilled in the art that this modification falls in the scope of the present invention as long as it includes the technical gist of the present invention.

Meanwhile, depending on the configuration of the example embodiment, the first light emitting group L31 to the fourth light emitting group L34 may have the same forward voltage level as each other, or forward voltage levels different from each other. For example, in the case in which the first light emitting group L31 to the fourth light emitting group L34 are configured to include the different number of light emitting elements or in the case in which the first light emitting group L31 to the fourth light emitting group L34 have different types of series or parallel or series and parallel connection relationship, the first light emitting group L31 to the fourth light emitting group L34 have forward voltage levels different from each other. However, hereinafter, for convenience of explanation and understanding, the present example embodiment will be described based on an example embodiment in which the light emitting unit 350 is configured to have the first forward voltage level VF1 of 50V, the second forward voltage level VF2 of 100V, the third forward voltage level VF3 of 150V, and the fourth forward voltage level VF4 of 200V.

In order to implement the free voltage function as described above, the control signal generator 310 according to the third example embodiment of the present invention is configured to detect the average voltage level per period of the driving voltage Vin and determine the standard of the AC power to which the illumination apparatus is currently connected, based on the detected average voltage level. In addition, the control signal generator 310 is configure to generate switch control signals SW1 to SW3 according to the determined standard of the AC power to output the switch control signals SW1 to SW3 to the first switch 121 to the third switch 123. For example, in the case in which the standard of the AC power connected to the illumination apparatus needs to connect the first light emitting group L31 to the fourth light emitting group L34 to be in parallel to each other, for example, in the case in which the AC power connected to the illumination apparatus is 60V(rms), the control signal generator 310 is configured to generate the switch control signals SW1 to SW3 that turn on all of the first switch 121 to the third switch 123 to output the switch control signals SW1 to SW3 to the first switch 121 to the third switch 123. Accordingly, all of the first switch 121 to the third switch 123 are tuned on, such that all of the first light emitting group L31 to the fourth light emitting group L34 are connected in parallel to each other to be driven.

In addition, in the case in which the standard of the AC power connected to the illumination apparatus needs to divide the first light emitting group L31 to the fourth light emitting group L34 into the subsets to be connected in parallel to each other, for example, in the case in which the AC power connected to the illumination apparatus is 120V(rms), the control signal generator 310 is configured to generate the switch control signals SW1 to SW3 that turn off the first switch 121 and the third switch 123 and turn on the second switch 122 to output the switch control signals SW1 to SW3 to the first switch 121 to the third switch 123. Accordingly, only the second switch 122 is turned on, such that a first set of light emitting groups (the first light emitting group L31 and the second light emitting group L32 connected in series with each other) and a second set of light emitting groups (the third light emitting group L33 and the fourth light emitting group L34 connected in series with each other) are connected in parallel to each other to be driven independently from each other. In addition, in this state, the first light emitting group L31 and the second light emitting group L32 within the first set of light emitting groups (the first light emitting group L31 and the second light emitting group L32 connected in series with each other) are sequentially driven according to the voltage level of the driving voltage Vin, and independently from those described above, the second light emitting group L32 and the third light emitting group L33 within the second set of light emitting groups (the third light emitting group L33 and the fourth light emitting group L34 connected in series with each other) are sequentially driven according to the voltage level of the driving voltage Vin.

In addition, in the case in which the standard of the AC power connected to the illumination apparatus may drive the first light emitting group L31 to the fourth light emitting group L34 to be in series with each other, for example, in the case in which the AC power connected to the illumination apparatus is 220V(rms), the control signal generator 310 is configured to generate the switch control signals SW1 to SW3 that turn off all of the first switch 121 to the third switch 123 to output the switch control signals SW1 to SW3 to the first switch 121 to the third switch 123. Accordingly, all of the first light emitting group L31 to the fourth light emitting group L34 are connected in series with each other to be sequentially driven according to the voltage level of the driving voltage Vin.

Meanwhile, since the average voltage level per period of the driving voltage Vin is not varied over time and is constant, the above-mentioned series and parallel connection control is performed only once when the illumination apparatus of the light emitting element according to the third example embodiment is initially started.

In addition, according to an example embodiment, the control signal generator 310 and the current controller 330 according to the third example embodiment of the present invention may be configured to perform a series of functions for controlling a sequential driving of at least some of the first light emitting group L31 to the fourth light emitting group L34.

The above-mentioned sequential driving control of the first light emitting group L31 to the fourth light emitting group L34 may be implemented by the control signal generator 310 that detects an instantaneous value of the driving voltage Vin and selectively activates a first driving current controller 331 to a fourth driving current controller 334 based on the detected instantaneous value. More specifically, the control signal generator 310 according to the present invention may control operation states of the first light emitting group L31 to the fourth light emitting group L34 by controlling activation and inactivation of the first driving current controller 331 to the fourth driving current controller 334, respectively, depending on a comparison result input from a comparing module 520.

The first driving current controller 331, the second driving current controller 332, the third driving current controller 333, and the fourth driving current controller 334 may be activated or inactivated according to the control of the control signal generator 310 as described above. More specifically, the first driving current controller 331 may be configured to connect or separate a first current path P1 thereto or therefrom according to the control of the control signal generator 310, the second driving current controller 332 may be configured to connect or separate a second current path P2 thereto or therefrom according to the control of the control signal generator 310, and the third driving current controller 333 may be configured to connect or separate a third current path P3 thereto or therefrom according to the control of the control signal generator 310. Similarly, the fourth driving current controller 334 may be configured to connect or separate a fourth current path P4 thereto or therefrom according to the control of the control signal generator 310.

In addition, similar to those described above about the first example embodiment and the second example embodiment, the first driving current controller 331, the second driving current controller 332, the third driving current controller 333, and the fourth driving current controller 334 may be configured to control a current value of a driving current IL of the light emitting element flowing through the respective switches according to the control of the control signal generator 310. The first driving current controller 331 to the fourth driving current controller 334 described above may be implemented to be identical or similar to the driving current controller according to the first example embodiment shown in FIG. 3.

In addition, according to an example embodiment, the control signal generator 310 according to the present invention may be further configured to control magnitude of the driving current IL of the light emitting element according to the determined standard of the AC power. That is, for example, since input powers input to the illumination apparatus of the light emitting element according to the third example embodiment from the AC power of 120V(rms), the AC power of 220V(rms), and the AC power of 277V(rms), respectively, need to be the same, the control signal generator 310 according to the present invention is configured to control the magnitude of the driving current IL of the light emitting element according to the determined standard of the AC power so that deviation of the input power for each AC power may be within a range of 10% to 30%. That is, the control signal generator 310 is configured to control a value of the driving current IL of the light emitting element for each AC power so that a relationship which is in inverse proportion to the effective voltage value of the AC power connected to the illumination apparatus is established.

Meanwhile, FIG. 11A is a waveform diagram illustrating a relationship between the driving voltage Vin and the driving current IL of the light emitting element in the case in which the illumination apparatus of a high efficiency light emitting element according to the third example embodiment is connected to the AC power of 120V(rms), and FIG. 11B is a waveform diagram illustrating a relationship between the driving voltage Vin and the driving current IL of the light emitting element in the case in which the illumination apparatus of the high efficiency light emitting element according to the third example embodiment is connected to the AC power of 220V(rms). In the case of the example embodiments shown in FIGS. 11A and 11B, as described above, it is assumed that the light emitting unit 350 is configured to have the first forward voltage level VF1 of 50V, the second forward voltage level VF2 of 100V, the third forward voltage level VF3 of 150V, and the fourth forward voltage level VF4 of 200V. Hereinafter, operations of the cases in which the illumination apparatus of the light emitting element according to the third example embodiment of the present invention as described above is connected to the AC power of 120V(rms) and the AC power of 220 (rms), respectively, will be described with reference to FIGS. 11A and 11B.

First, as described above, the AC power of 120V(rms) is an AC power which may not drive the first light emitting group L31 to the fourth light emitting group L34 in the state in which the first light emitting group L31 to the fourth light emitting group L34 are connected in series with each other, and needs to be controlled to be divided into the first set of light emitting groups (the first light emitting group L31 and the second light emitting group L32 connected in series with each other) and the second set of light emitting groups (the third light emitting group L33 and the fourth light emitting group L34 connected in series with each other) so that the first set of light emitting groups and the second set of light emitting groups are connected in parallel to each other. Therefore, the control signal generator 310 generates the switch control signals SW1 to SW3 that turn off the first switch 121 and the third switch 123 and turn on the second switch 122 to output the switch control signals SW1 to SW3 to the first switch 121 to the third switch 123, and accordingly, only the second switch 122 is turned on, such that the first set of light emitting groups (the first light emitting group L31 and the second light emitting group L32 connected in series with each other) and the second set of light emitting groups (the third light emitting group L33 and the fourth light emitting group L34 connected in series with each other) are connected in parallel to each other to be driven independently from each other. In this state, a relationship between the driving voltage Vin and the driving current IL of the light emitting element flowing through the first set of light emitting groups, that is, the first light emitting group L31 and the second light emitting group L32 connected in series with each other is shown in an upper side of FIG. 11A, and a relationship between the driving voltage Vin and the driving current IL of the light emitting element flowing through the second set of light emitting groups, that is, the third light emitting group L33 and the fourth light emitting group L34 connected in series with each other is shown in a lower side of FIG. 11A. As can be seen from the upper and lower sides of the FIG. 11A, the first set of light emitting groups and the second set of light emitting groups are independently controlled in the state in which the first set of light emitting groups and the second set of light emitting groups are connected in parallel to each other. Particularly, it may be seen that the first light emitting group L31 and the second light emitting group L32 belonging to the first set of light emitting groups are sequentially driven according to the voltage level of the driving voltage Vin. That is, as shown in the upper side of the FIG. 11A, in a section in which the voltage level of the driving voltage Vin is the first forward voltage level VF1 or more and is less than the second forward voltage level VF2, the first driving current controller 331 is activated and the second driving current controller 332 is inactivated, such that only the first light emitting group L31 of the first set of light emitting groups emits light. In addition, in a section in which the voltage level of the driving voltage Vin is the second forward voltage level VF2 or more, the first driving current controller 331 is inactivated and the second driving current controller 332 is activated, such that all of the first light emitting group L31 and the second light emitting group L32 of the first set of light emitting groups are emitted. Therefore, it may be seen that the sequential driving according to the voltage level of the driving voltage Vin is performed within the first set of light emitting groups.

In addition, independently, the third light emitting group L33 and the fourth light emitting group L34 belonging to the second set of light emitting groups are sequentially driven according to the voltage level of the driving voltage Vin. That is, as shown in the lower side of the FIG. 11A, in a section in which the voltage level of the driving voltage Vin is ‘the third forward voltage level VF3−the second forward voltage level VF2’ (VF3−VF2) or more and is less than ‘the fourth forward voltage level VF4−the second forward voltage level VF2’ (VF4−VF2), the third driving current controller 333 is activated and the fourth driving current controller 334 is inactivated, such that only the third light emitting group L33 of the second set of light emitting groups emits light. In addition, in a section in which the voltage level of the driving voltage Vin is ‘the fourth forward voltage level VF4−the second forward voltage level VF2’ (VF4−VF2) or more, the third driving current controller 333 is inactivated and the fourth driving current controller 334 is activated, such that all of the third light emitting group L33 and the fourth light emitting group L34 of the second set of light emitting groups are emitted. Therefore, it may be seen that the sequential driving according to the voltage level of the driving voltage Vin is performed within the second set of light emitting groups.

On the other hand, as described above, the AC power of 220V(rms) is an AC power that may drive the first light emitting group L31 to the fourth light emitting group L34 in the state in which the first light emitting group L31 to the fourth light emitting group L34 are connected in series with each other. Therefore, all of the first switch 121 to the third switch 123 are maintained in an opened state according to the control of the control signal generator 310, and the first light emitting group L31 to the fourth light emitting group L34 are sequentially driven by the control signal generator 310 in the state in which the first light emitting group L31 to the fourth light emitting group L34 are connected in series with each other. The above-mentioned process is shown in FIG. 11B. That is, as shown in FIG. 11B, in the section in which the voltage level of the driving voltage Vin is the first forward voltage level VF1 or more and is less than the second forward voltage level VF2, only the first driving current controller 331 is activated and other driving current controllers are inactivated, such that only the first light emitting group L31 emits light. In addition, in the section in which the voltage level of the driving voltage Vin is the second forward voltage level VF2 or more and is less than the third forward voltage level VF3, only the second driving current controller 332 is activated and other driving current controllers are inactivated, such that the first light emitting group L31 and the second light emitting group L32 are emitted. In addition, in a section in which the voltage level of the driving voltage Vin is the third forward voltage level VF3 or more and is less than the fourth forward voltage level VF4, only the third driving current controller 333 is activated and other driving current controllers are inactivated, such that the first light emitting group L31 to the third light emitting group L33 are emitted. Finally, in a section in which the voltage level of the driving voltage Vin is the fourth forward voltage level VF4 or more, only the fourth driving current controller 334 is activated and other driving current controllers are inactivated, such that the first light emitting group L31 to the fourth light emitting group L34 are emitted. Therefore, as can be seen from the above, in the case in which the illumination apparatus is connected to the AC power of 220V(rms), it may be seen that the first light emitting group L31 to the fourth light emitting group L34 are connected in series with each other to be sequentially driven according to the voltage level of the driving voltage Vin.

In addition, as described above, the illumination apparatus of the light emitting element according to the third example embodiment of the present invention may control the magnitude of the driving current IL of the light emitting element for each AC power so that power deviation for each AC power of input power input to the illumination apparatus may be maintained within 10% to 30%. For example, a driving current IL′ of the light emitting element of the illumination apparatus of the light emitting element according to the third example embodiment connected to the AC power of 220V(rms) may be constant current-controlled to about ½ of the driving current IL of the light emitting element of the illumination apparatus of the light emitting element according to the third example embodiment connected to the AC power of 120V(rms). FIG. 11A shows a driving current IL1 of a first light emitting element, a driving current IL2 of a second light emitting element, a driving current IL3 of a third light emitting element, and a driving current IL4 of a fourth light emitting element of the illumination apparatus of the light emitting element according to the third example embodiment connected to the AC power of 120V(rms), and FIG. 11B shows a driving current IL1′ of the first light emitting element, a driving current IL2′ of the second light emitting element, a driving current IL3′ of the third light emitting element, and a driving current IL4′ of the fourth light emitting element of the illumination apparatus of the light emitting element according to the third example embodiment connected to the AC power of 220V(rms). Referring to FIGS. 11A and 11B, it may be seen that magnitude of the driving current IL1′ of the first light emitting element, magnitude of the driving current IL2′ of the second light emitting element, magnitude of the driving current IL3′ of the third light emitting element, and magnitude of the driving current IL4′ of the fourth light emitting element are constant current-controlled to about ½ of magnitude of the driving current IL1 of the first light emitting element, magnitude of the driving current IL2 of the second light emitting element, magnitude of the driving current IL3 of the third light emitting element, and magnitude of the driving current IL4 of the fourth light emitting element.

Hereinabove, various example embodiments of the illumination apparatus of the high efficiency light emitting element according to the present invention have been described with reference to the accompanying drawings. As described above, the illumination apparatus of the high efficiency light emitting element according to the present invention may control the series and parallel connection relationship between the light emitting groups according to the voltage level of the driving voltage, and may improve power efficiency thereof by controlling the sequential driving the light emitting groups, at the same time. In addition, the illumination apparatus of the high efficiency light emitting element according to the present invention may further improve power efficiency thereof by blocking an input of the rectified voltage in the compensation section. 

What is claimed is:
 1. An illumination apparatus, comprising: a rectifier configured to be connected to an alternating current (AC) power source and to perform a full-wave rectification for an applied AC voltage, and to provide a rectified voltage which is full-wave rectified to a light emitting unit as a driving voltage, the light emitting unit comprising a first light emitting group to an n-th light emitting group, n being a positive integer of at least two, and configured to emit light by receiving the driving voltage from the rectifier; a control signal generator configured to generate a switch control signal for controlling a series and parallel connection relationship between the first light emitting group to the n-th light emitting group according to an average voltage level per period of the driving voltage, and generate a current control signal for controlling a sequential driving of at least a portion of the first light emitting group to the n-th light emitting group according to the voltage level of the driving voltage; a switch unit configured to perform an on or off operation according to the switch control signal, to selectively transfer the driving voltage; and a current controller comprising a first driving current controller to an n-th driving current controller connected to the first light emitting group to the n-th light emitting group, respectively, the first driving current controller to the n-th driving current controller configured to be selectively activated according to the current control signal.
 2. The illumination apparatus of claim 1, wherein the control signal generator is configured to control the magnitude of a driving current of the light emitting element according to the average voltage level per period of the driving voltage.
 3. A driving circuit of a light emitting element configured to control driving of a light emitting unit comprising a first light emitting group to an n-th light emitting group, n being a positive integer of two or more, the driving circuit comprising: a rectifier configured to be connected to an alternating current (AC) power source, perform a full-wave rectification for an applied AC voltage, and to provide a rectified voltage which is full-wave rectified to a light emitting unit as a driving voltage; a control signal generator configured to generate a switch control signal for controlling a series and parallel connection relationship between the first light emitting group to the n-th light emitting group according to an average voltage level per period of the driving voltage, and generate a current control signal for controlling a sequential driving of at least a portion of the first light emitting group to the n-th light emitting group according to the voltage level of the driving voltage; a switch unit configured to perform an on or off operation according to the switch control signal, to selectively transfer the driving voltage; and a current controller comprising a first driving current controller to an n-th driving current controller connected to the first light emitting group to the n-th light emitting group, respectively, the first driving current controller to the n-th driving current controller configured to be selectively activated according to the current control signal.
 4. The driving circuit of claim 3, wherein the control signal generator is configured to control the magnitude of a driving current of the light emitting element according to the average voltage level per period of the driving voltage. 